The cblD defect causes either isolated or combined deficiency of methylcobalamin and adenosylcobalamin synthesis

Intracellular cobalamin is converted to adenosylcobalamin, coenzyme for methylmalonyl-CoA mutase and to methylcobalamin, coenzyme for methionine synthase, in an incompletely understood sequence of reactions. Genetic defects of these steps are defined as cbl complementation groups of which cblC, cblD (described in only two siblings), and cblF are associated with combined homocystinuria and methylmalonic aciduria. Here we describe three unrelated patients belonging to the cblD complementation group but with distinct biochemical phenotypes different from that described in the original cblD siblings. Two patients presented with isolated homocystinuria and reduced formation of methionine and methylcobalamin in cultured fibroblasts, defined as cblD-variant 1, and one patient with isolated methylmalonic aciduria and deficient adenosylcobalamin synthesis in fibroblasts, defined as cblD-variant 2. Cell lines from the cblD-variant 1 patients clearly complemented reference lines with the same biochemical phenotype, i.e. cblE and cblG, and the cblD-variant 2 cell line complemented cells from the mutant classes with isolated deficiency of adenosylcobalamin synthesis, i.e. cblA and cblB. Also, no pathogenic sequence changes in the coding regions of genes associated with the respective biochemical phenotypes were found. These findings indicate heterogeneity within the previously defined cblD mutant class and point to further complexity of intracellular cobalamin metabolism.     

Cloning of multiple genes involved with cobalamin (Vitamin B12) biosynthesis in Bacillus megaterium.

An effective shotgun cloning procedure was developed for Bacillus megaterium by amplifying gene libraries in Bacillus subtilis. This technique was useful in isolating at least 11 genes from B. megaterium which are involved with cobalamin (vitamin B12) biosynthesis. Amplified plasmid banks were transformed into protoplasts of both a series of Cob mutants blocked before the biosynthesis of cobinamide and Cbl mutants blocked in the conversion of cobinamide into cobalamin. Amplification of gene libraries overcame the cloning barriers inherent in the relatively low protoplast transformation frequency of B. megaterium. A family of plasmids was isolated by complementation of seven different Cob and Cbl mutants. Each plasmid capable of complementing a Cob or Cbl mutant was transformed into each one of the series of Cob and Cbl mutants; many of the plasmids isolated by complementation of one mutation carried genetic activity for complementation of other mutations. By these criteria, four different complementation groups were resolved. At least six genes involved in the biosynthesis of cobinamide are carried on a fragment of DNA approximately 2.7 kilobase pairs in length; other genes involved in the biosynthesis of cobinamide were located in two other complementation groups. The physical and genetic data permitted an ordering of genes within several of the complementation groups. The presence of complementing plasmids in mutants blocked in cobalamin synthesis resulted in restoration of cobalamin biosynthesis.     

Cloning and analysis of genes involved in coenzyme B12 biosynthesis in Pseudomonas denitrificans.

Cobalamin synthesis probably requires 20 to 30 different enzymatic steps. Pseudomonas putida and Agrobacterium tumefaciens mutants deficient in cobalamin synthesis (Cob have been isolated. In P. putida, Cob mutants were identified as being unable to use ethanolamine as a source of nitrogen in the absence of added cobalamin (deamination of ethanolamine requires coenzyme B12 as a cofactor). In A. tumefaciens, Cob mutants were simply screened for their reduced cobalamin synthesis. A genomic library of Pseudomonas denitrificans was constructed on a mobilizable wide-host-range vector. Eleven plasmids from this library were able to complement most of these mutants. By complementation and restriction mapping analysis, four genomic loci of P. denitrificans were found to be responsible for complementation of the Cob mutants. By subcloning fragments from the four genomic loci, we identified at least 14 different genes involved in cobalamin synthesis.     

Membrane mutants of animal cells: rapid identification of those with a primary defect in glycosylation.

Membrane mutants of animal cells have been isolated by several laboratories, using a variety of selection protocols. The majority are lectin receptor mutants arising from altered glycosylation of membrane molecules. They have been obtained by selection for resistance to cytotoxic plant lectins or by alternative protocols designed, in many cases, to isolate different classes of receptor mutants. The identification of most membrane mutants expressing altered surface carbohydrates is rapidly achieved by determining their resistance to several lectins of different carbohydrate-binding specificities. For Chinese hamster ovary mutants, genetic novelty may subsequently be determined by complementation analysis with selected members of 10 recessive, glycosylation-defective complementation groups defined by this laboratory. In an attempt to identify new complementation groups, 11 Chinese hamster ovary membrane mutants independently isolated in different laboratories have been investigated for their lectin resistance and complementation properties. Only one new complementation group was defined by these studies. The remaining 10 mutants fell into complementation group 1, 2, 3, or 8. Although no evidence for intragenic complementation was observed, indirect evidence for different mutations within some genes was obtained. Seven of the independent isolates fell into complementation group 1, reflecting the high probability of isolating the Lec1 phenotype from Chinese hamster ovary populations. The results emphasize the importance of performing a genetic analysis before biochemical characterization of putative new membrane mutants.     

Genetic characterization of the pdu operon: use of 1,2-propanediol in Salmonella typhimurium.

Salmonella typhimurium is able to catabolize 1,2-propanediol for use as the sole carbon and energy source; the first enzyme of this pathway requires the cofactor adenosyl cobalamin (Ado-B12). Surprisingly, Salmonella can use propanediol as the sole carbon source only in the presence of oxygen but can synthesize Ado-B12 only anaerobically. To understand this situation, we have studied the pdu operon, which encodes proteins for propanediol degradation. A set of pdu mutants defective in aerobic degradation of propanediol (with exogenous vitamin B12) defines four distinct complementation groups. Mutations in two of these groups (pduC and pduD) eliminate propanediol dehydratase activity. Based on mutant phenotypes, a third complementation group (pduG) appears to encode a cobalamin adenosyl transferase activity. No function has been assigned to the pduJ complementation group. Propionaldehyde dehydrogenase activity is eliminated by mutations in any of the four identified complementation groups, suggesting that this activity may require a complex of proteins encoded by the operon. None of the mutations analyzed affects either of the first two genes of the operon (pduA and pduB), which were identified by DNA sequence analysis. Available data suggest that the pdu operon includes enough DNA for about 15 genes and that the four genetically identified genes are the only ones required for aerobic use of propanediol.     

The structural basis for methylmalonic aciduria. The crystal structure of archaeal ATP:cobalamin adenosyltransferase

ATP:cobalamin adenosyltransferase MMAB was recently identified as the gene responsible for a disorder of cobalamin metabolism in humans (cblB complementation group). The crystal structure of the MMAB sequence homologue from Thermoplasma acidophilum (TA1434; GenBank identification number gi|16082403) was determined to a resolution of 1.5 A. TA1434 was confirmed to be an ATP:cobalamin adenosyltransferase, which depended absolutely on divalent metal ions (Mg2+ > Mn2+ > Co2+) and only used ATP or dATP as adenosyl donors. The apparent Km of TA1434 was 110 microM (kcat = 0.23 s(-1)) for ATP, 140 microM (kcat = 0.11 s(-1)) for dATP, and 3 microM (kcat = 0.18 s(-1)) for cobalamin. TA1434 is a trimer in solution and in the crystal structure, with each subunit composed of a five-helix bundle. The location of disease-related point mutations and other residues conserved among the homologues of TA1434 suggest that the active site lies at the junctions between the subunits. Mutations in TA1434 that correspond to the disease-related mutations resulted in proteins that were inactive for ATP:cobalamin adenosyltransferase activity in vitro, confirming that these mutations define the molecular basis of the human disease.     

Translational regulation by non-protein-coding RNAs: different targets, common themes

There are several classes of small non-protein-coding RNA (npcRNA) that play important roles in cellular metabolism including mRNA decoding, RNA processing and mRNA stability. Indeed, altered expression of some of these npcRNAs has been associated with cancer, neurodegenerative diseases such as Alzheimer’s disease, as well as various types of mental retardation and psychiatric disorders. The basis of this correlation is currently not understood. However, recent studies have begun to shed light on one of the mechanism(s) by which these RNAs exert their effects, namely, translational control. These data provide hope that rational treatments for these varied disorders may be in sight. Here, we review this new body of work.     

Blood cobalamins and xenobiotic-metabolizing enzymes in rat liver in adjuvant arthritis]

Changes in the total cobalamin content and spectrum of individual forms of these vitamins in blood cells and plasma as well as the activities of enzymatic systems of xenobiotic metabolism in liver microsomes of rats with experimental adjuvant arthritis (AA) have been studied. The total cobalamin content in the blood plasma of rats with AA was increased in comparison with intact animals; however, leucocytes from AA rats were deficient in methylcobalamin (MeCbl). A correlation was found between the ratios of individual cobalamin forms and their total content which was differently expressed in experimental and control animals. The development of AA was associated with marked inhibition of the cytochrome P-450-dependent monooxygenase system of the liver and glutathione transferase. The possibility of correction of these disturbances by MeCbl is discussed.     

Genetic analysis, nucleotide sequence, and products of two Pseudomonas denitrificans cob genes encoding nicotinate-nucleotide: dimethylbenzimidazole phosphoribosyltransferase and cobalamin (5''-phosphate) synthase.

Tn5 Sp(r) transposons have been inserted into the 8-kb Pseudomonas denitrificans DNA fragment from complementation group D, which carries cob genes. Genetic analysis and the nucleotide sequence revealed that only two cob genes (cobU and cobV) were found on this cob genomic locus. Nicotinate-nucleotide: dimethylbenzimidazole phosphoribosyltransferase (EC 2.4.2.21) was assayed and purified to homogeneity from a P. denitrificans strain in which cobU and cobV were amplified. The purified enzyme was identified as the cobU gene product on the basis of identical molecular weights and N-terminal sequences. Cobalamin (5'-phosphate) synthase activity was increased when cobV was amplified in P. denitrificans. The partially purified enzyme catalyzed not only the synthesis of cobalamin 5'-phosphate from GDP-cobinamide and alpha-ribazole 5'-phosphate but also the one-step synthesis of cobalamin from GDP-cobinamide and alpha-ribazole. Biochemical data provided evidence that cobV encodes cobalamin (5'-phosphate) synthase.     

The cobalamin (coenzyme B12) biosynthetic genes of Escherichia coli.

The enteric bacterium Escherichia coli synthesizes cobalamin (coenzyme B12) only when provided with the complex intermediate cobinamide. Three cobalamin biosynthetic genes have been cloned from Escherichia coli K-12, and their nucleotide sequences have been determined. The three genes form an operon (cob) under the control of several promoters and are induced by cobinamide, a precursor of cobalamin. The cob operon of E. coli comprises the cobU gene, encoding the bifunctional cobinamide kinase-guanylyltransferase; the cobS gene, encoding cobalamin synthetase; and the cobT gene, encoding dimethylbenzimidazole phosphoribosyltransferase. The physiological roles of these sequences were verified by the isolation of Tn10 insertion mutations in the cobS and cobT genes. All genes were named after their Salmonella typhimurium homologs and are located at the corresponding positions on the E. coli genetic map. Although the nucleotide sequences of the Salmonella cob genes and the E. coli cob genes are homologous, they are too divergent to have been derived from an operon present in their most recent common ancestor. On the basis of comparisons of G+C content, codon usage bias, dinucleotide frequencies, and patterns of synonymous and nonsynonymous substitutions, we conclude that the cob operon was introduced into the Salmonella genome from an exogenous source. The cob operon of E. coli may be related to cobalamin synthetic genes now found among non-Salmonella enteric bacteria.     

An usage of cultured human cell lines in studies of inherited metabolic disease

Cultured skin fibroblasts and lymphoblastoid lines (established by Epstein-Barr infection) derived from patients have been commonly used in studies on inherited metabolic disorders. It is generally accepted that, on some occasions, valuable information for comprehending the normal transport function and intracellular metabolism in human cells only becomes available through studies using affected cells, and not normal cells. Besides clarification of the mechanism an abnormal function caused by a mutant enzyme, cultured cells provide other useful information (or products), with advanced procedures including cell fusion and gene technology; genetic heterogeneity (gene complementation analysis), correction of mutant genes (transfer of genes or gene products), gene cloning of a specific locus (using chromosomal deletion) and gene expression. The application of "reverse genetics" may permit further access to a complex cellular system.     

Genes from the cyanobacterium Agmenellum quadruplicatum isolated by complementation: characterization and production of merodiploids

The isolation of several biosynthetic genes from a cyanobacterium, Agmenellum quadruplicatum, by complementation of auxotrophic mutations in Escherichia coli, and their partial characterization, is described. Although our search for such genes has not been exhaustive, it appears that complementation of E. coli mutations may be of limited utility for the identification and/or isolation of cyanobacterial genes. Despite some overlap in the complementation abilities of these isolated cyanobacterial DNA fragments, the genes that we have studied in some detail are not located in operons. We have used mutagenized versions of these cyanobacterial DNA fragments to produce mutant phenotypes in the cyanobacterium, but clean auxotrophs were not obtained. Complementation of these mutant phenotypes can be obtained when the appropriate wild-type DNA fragment is introduced into the cyanobacterium on a shuttle vector. Recombination between two copies of a cyanobacterial gene occurs at high frequency in the cyanobacterium.     

Isolation and genetic characterizations of Bacillus megaterium cobalamin biosynthesis-deficient mutants

Ethanolamine is deaminated by the action of ethanolamine ammonia-lyase (EC 4.3.1.7), an adenosylcobalamin-dependent enzyme. Consequently, to grow on ethanolamine as a sole nitrogen source, Bacillus megaterium requires vitamin B12. Identification of B. megaterium mutants deficient for growth on ethanolamine as the sole nitrogen source yielded a total of 34 vitamin B12 auxotrophs. The vitamin B12 auxotrophs were divided into two major phenotypic groups: Cob mutants, which could use cobinamide or vitamin B12 to grow on ethanolamine, and Cbl mutants, which could be supplemented only by vitamin B12. The Cob mutants were resolved into six classes and the Cbl mutants were resolved into three, based on the spectrum of cobalt-labeled corrinoid compounds which they accumulated. Although some radiolabeled cobalamin was detected in the wild type, little or none was evident in the auxotrophs. The results indicate that Cob mutants contain lesions in biosynthetic steps before the synthesis of combinamide, while Cbl mutants are defective in the conversion of cobinamide to cobalamin. Analysis of phage-mediated transduction experiments revealed tight genetic linkage within the Cob class and within the Cbl class. Similar transduction analysis indicated the Cob and Cbl classes are weakly linked. In addition, cross-feeding experiments in which extracts prepared from mutants were examined for their effect on growth of various other mutants allowed a partial ordering of mutations within the cobalamin biosynthetic pathway.     

An F1 genetic screen for maternal-effect mutations affecting embryonic pattern formation in Drosophila melanogaster

Large-scale screens for female-sterile mutations have revealed genes required maternally for establishment of the body axes in the Drosophila embryo. Although it is likely that the majority of components involved in axis formation have been identified by this approach, certain genes have escaped detection. This may be due to (1) incomplete saturation of the screens for female-sterile mutations and (2) genes with essential functions in zygotic development that mutate to lethality, precluding their identification as female-sterile mutations. To overcome these limitations, we performed a genetic mosaic screen aimed at identifying new maternal genes required for early embryonic patterning, including zygotically required ones. Using the Flp-FRT technique and a visible germline clone marker, we developed a system that allows efficient screening for maternal-effect phenotypes after only one generation of breeding, rather than after the three generations required for classic female-sterile screens. We identified 232 mutants showing various defects in embryonic pattern or morphogenesis. The mutants were ordered into 10 different phenotypic classes. A total of 174 mutants were assigned to 86 complementation groups with two alleles on average. Mutations in 45 complementation groups represent most previously known maternal genes, while 41 complementation groups represent new loci, including several involved in dorsoventral, anterior-posterior, and terminal patterning.     

Heterogeneity in cblG: differential retention of cobalamin on methionine synthase.

Cultured fibroblasts from patients with functional methionine synthase deficiency have been shown to belong to two complementation classes, cblE and cblG. Both are associated with decreased intracellular levels of methylcobalamin (MeCbl) and decreased incorporation of label from 5-methyltetrahydrofolate into macromolecules. Methionine synthase specific activity is normal or near normal in cell extracts from cblE patients under standard reducing conditions, whereas specific activity is low in cblG extracts. Seven of 10 cblG cell lines accumulated [57Co]CN-Cbl equivalent to control cells and showed similar proportions of label associated with the two intracellular cobalamin binders, methionine synthase and methylmalonyl-CoA mutase. The remaining three cblG lines showed reduced accumulation of labeled Cbl and virtually none associated with methionine synthase. The specific activity of methionine synthase was decreased in cell extracts from both cblG subgroups, being almost undetectable in extracts from the latter three lines. Incorporation of label from [14C]MeTHF into either macromolecules or into methionine was decreased in both cblG groups, but was paradoxically higher in the three lines with very low in vitro methionine synthase activity. These results demonstrate further heterogeneity within cblG and suggest that the defect in the three variant lines affects the ability of methionine synthase to retain Cbl.     

Oxidative stress and apoptosis in homocystinuria patients with genetic remethylation defects

Oxidative stress has been described as a putative disease mechanism in pathologies associated with an elevation of homocysteine. An increased reactive oxygen species (ROS) production and apoptosis rate have been associated with several disorders of cobalamin metabolism, particularly with methylmalonic aciduria (MMA) combined with homocystinuria cblC type. In this work, we have evaluated several parameters related to oxidative stress and apoptosis in fibroblasts from patients with homocystinuria due to defects in the MTR, MTRR, and MTHFR genes involved in the remethylation pathway of homocysteine. We have also evaluated these processes by knocking down the MTRR gene in cellular models, and complementation by transducing the wild‐type gene in cblE mutant fibroblasts. All cell lines showed a significant increase in ROS content and in MnSOD expression level, and also a higher rate of apoptosis with similar levels to the ones in cblC fibroblasts. The amount of the active phosphorylated forms of p38 and JNK stress‐kinases was also increased. ROS content and apoptosis rate increased in control fibroblasts and in a glioblastoma cell line by shRNA‐mediated silencing of MTRR gene expression. In contrast, wild‐type MTRR gene corrected mutant cell lines showed a decrease in ROS and apoptosis levels. To the best of our knowledge, this study provides the first evidence that an impaired remethylation capacity due to low MTRR and MTR activity might be partially responsible for stress response. J. Cell. Biochem. 114: 183–191, 2012. © 2012 Wiley Periodicals, Inc.     

Nuclear functions required for cytochrome c oxidase biogenesis in Saccharomyces cerevisiae. Characterization of mutants in 34 complementation groups

To identify nuclear functions required for cytochrome c oxidase biogenesis in yeast, recessive nuclear mutants that are deficient in cytochrome c oxidase were characterized. In complementation studies, 55 independently isolated mutants were placed into 34 complementation groups. Analysis of the content of cytochrome c oxidase subunits in each mutant permitted the definition of three phenotypic classes. One class contains three complementation groups whose strains carry mutations in the COX4, COX5a, or COX9 genes. These genes encode subunits IV, Va, and VIIa of cytochrome c oxidase, respectively. Mutations in each of these structural genes appear to affect the levels of the other eight subunits, albeit in different ways. A second class contains nuclear mutants that are defective in synthesis of a specific mitochondrial-encoded cytochrome c oxidase subunit (I, II, or III) or in both cytochrome c oxidase subunit I and apocytochrome b. These mutants fall into 17 complementation groups. The third class is represented by mutants in 14 complementation groups. These strains contain near normal amounts of all cytochrome c oxidase subunits examined and therefore are likely to be defective at some step in holoenzyme assembly. The large number of complementation groups represented by the second and third phenotypic classes suggest that both the expression of the structural genes encoding the nine polypeptide subunits of cytochrome c oxidase and the assembly of these subunits into a functional holoenzyme require the products of many nuclear genes.     

Rapid prenatal and postnatal detection of inborn errors of propionate,methylmalonate, and cobalamin metabolism: A sensitive assay using cultured cells

Summary A sensitive, reliable, and easily performed procedure is described for the prenatal and postnatal detection of inborn errors of propionate, methylmalonate, and cobalamin metabolism using cultured amniotic cells and skin fibroblasts. With this assay, control fibroblast lines incorporated a mean of 6.89 nanoatoms ¹⁴C/mg protein from [1-¹⁴C]propionate into trichloroacetic acid (TCA)-precipitable cell material in 10h. Twenty-five mutant fibroblast lines from patients with propionicacidemia or one of the methylmalonicacidemias fixed 0.04 to 0.93 nanoatoms ¹⁴C/mg. Considerable variation was observed, both among and within discrete mutant classes, with respect to the residual amount of propionate pathway activity, possibly reflecting further molecular heterogeneity in these disorders.We applied this procedure to cultured amniotic cells from controls and 4 midtrimester pregnancies at risk for methylmalonicacidemia and diagnosed one fetus with a methylmalonyl CoA apomutase defect and 3 fetuses which were unaffected.Presented in part at the annual meeting of the Society for Pediatric Research, St. Louis, Missouri, April 1976.     

Genetic analysis of leaf form mutants from the Arabidopsis Information Service collection

Although a vast inventory of morphological mutants of Arabidopsis thaliana is available, only some have been used for genetic studies of leaf development. Such is the case with the Arabidopsis Information Service (AIS) Form Mutants collection, assembled by A. R. Kranz and currently stored at the Nottingham Arabidopsis Stock Centre, which includes a large number of mutant lines, most of which have been little studied. With the aim of contributing to the genetic dissection of leaf ontogeny, we have subjected 57 mutant lines isolated by others to genetic analysis; 47 of which were from the AIS collection. These are characterized by vegetative leaves of abnormal shape or size, and were chosen as candidates for mutations in genes required for leaf morphogenesis. The mutant phenotypes studied were shown to be inherited as single recessive Mendelian traits and were classified into 10 phenotypic classes. These mutant strains were found to fall into 37 complementation groups, 7 of which corresponded to known genes. Results of the phenotypic analysis and data on the genetic interactions of these mutants are presented, and their possible developmental defects discussed.